Water treating apparatus



gime 49 E935.. E. Tl TURNER WATER TREATING APPARATUS Filed oct. 9, 1951 4 Sheets-Sheet l n.2 an. IPSE a En@ u 27mm humz .IES R RE Y 0N E WW m T m 1 wm M .E .5 k NN M. M m Q. .mi mm Sq w N x June 4, 1935. E, IT, TURNER 2,903,762

WATER TREATING APPARATUS Filed Oct.v9, 1951 4 Smets-sheet 2 /N VEN TOF?.

EDWARD 7T TURNER. by

June y4, 1935.

E. T. TURNER 'WATER TEATNG APPARATUS v Filed oct. 9, 1931 4 Sheets-Sheet* 5 June 4, 1935. E, T, TURNER 2,003,762

WATER TREATING APPARATUS FiledOct. 9, 1931 4 Sheets-Sheet- 4 /NL/f/VTOR. b/VEDWA R0 7? TURNER.

/l/Ls ATM/#NEX LIN Patented June 4, 1935 UNITED. STATES WATER Tal-:Arme APPARATUS` Edward T. Turner. Dayton, ohio, assignmto The' Permutit Company, 1

934), Wilmington, Del., a

corporation of Delaware Application October 9,

- 30 Claims.

This invention relates to an apparatus for treating water for the purpose of softening the same and of removing foreign matter therefrom.

One object of the invention is to provide such an apparatus of large capacity, such as is required i'or municipal plants and the like, which will be simple in its operation and which maybe operated at a relatively low cost.

A further object of the invention is to provide such an apparatus which comprises one or more mineral containers, with improved means for delivering water to the mineral containers; and means for controlling the pressure at which the water is introduced into said containers.

A further object of the invention is to provide improved means for automatically controlling the reconditioning of the mineral.

y A further object ofthe invention is to provide such an apparatus in which the supply of water to the apparatus and the reconditioning mechanism will be electrically controlled and the elec-A tric controlling .means will in turn be controlled according to the amount of soft water used.

Other objects of the invention will appear as the apparatus is described in detail.

In the accompanying drawings Fig. l is a plan A view, partlyin section, of a portion of an apparatus embodying my invention and comprising two double softeningunits; Fig. 2 is a transverse section taken throughsuch anapparatus on line 2--2 of Fig..1; Fig. 3 is a transverse section taken through such an apparatus on line 3 3 of Fig. 1,

` and partly broken away; Fig. 4 is a vertical sectional view of the brine distributor; Fig. 5 is a bottom plan view of the delivery basin forming part of the brine distributor; Fig. 6 is a1 plan view ofthe brine distributor receptacle;.1i'ig. 7 is a transverse sectional view taken through the drain trough; Fig. 8 is a transverse sectional view of a portion of the apparatus showing a modiiied form of brine distributing mechanism; Fig. 9 is a diagramoithe electrical circuits; Fig. 10 is a tic illustration of a m ed installation, and Fig. 11 is a vertical sect1 n through the brine distributor taken on the line Il-v-II of Fig. 6. y

In these drawings I have-illustrated certain embodiments of my invention in the preferred embodiment, have shown the same as designed for a particular municipal installation but it will be understood that the apparatus may take various forms and'that theorganization and arrangement of the mechanism may vary indifferent installations.

In the installation here shown the apparatus 1931,.ser1a1 No. 561,913

(ci. zic-24) Y comprises a main structure of concrete which is partially embedded in the earth so that certain of the reservoirs and other parts of the apparatus are below the ground. This is .a convenient arrangement but is not essential to the invention. 5 The lower portion ofthe apparatus is divided into three compartments, a compartment i constituting a soft water reservoira compartment I constituting a ,salt reservoir or brine tank, and a compartment 1 constituting the` mechanism l0 chamber Vin which certain pumps, filters and so forth are arranged. The top wall I of these several compartments is, in the present instan at substantially the ground level and is provided with an opening 9 above the brine tank-to permit 16 thedelvery of salt thereto. 'I'he ,top wall 8 of the lower compartments constitutes the floor of the upper compartment. Mounted on this floor are the waterv softening unit or units and the# reconditioning mechanism. The apparatus may l0 comprise one or any desired number of soften- 1 ing units and each softening unit may vconsist of one Aor a plurality of softeners. Each softening unit is preferably controlled independently of the other softening units so that a sinle unit or any desired number of units may operate at a given time. lIn the arrangement shown in Fig. 1 .the apparatus comprises two double softening units, each unit consisting of two containers I0 for water softening material, such as zeolite, green sand or the like, and herein referred to as the mineral. The two containers are spaced some distance apart and eachis provided at a point above the level of the mineral therein with an outletfor the softened water. This outlet may be in the form of an opening Il formalin the wall of the container and preferably this opening communicates with a trough I2 on the outer side of the wall which has in its bottom an. opening I3 through which the fluid may be discharged. This opening is, in the present instance, arranged above an opening I4 inthe floor l above the soft water reservoir i so that the soft'water falls from the trough I2 through the opening I4 into the reservoir and is thus aerated and oxidized before delivery to the reservoir. vI prefer to provide each container'with a collecting trough I la which extends across the container above vthe mineral and communicates withthe outlet Il. The water flows over the edges of this trough throughout the width of the container and thus prevents channeling of the mineral which might result if the water flowed directly to the relatively v' small outlet.

The hard water which is to be softened may be ,ff

delivered to the containers in any suitablemanner but'I prefer to employ the ement here shown," in which I have u: between the two c ntainersf of each unit a structure, in the present instance of concrete,` which is divided by partitions I5 into three compartments, the outer coni'partments II constituting supply reservoirs' .from this outlet and delivers it to the container,

the pipebeing here shown as arranged beneath the oor`8 and provided with a plurality of distributing tubes (I9 which extend through the floorinto the lower portion of the container. This arrangement is'such that normally, that is when the apparatus is not in operation, the water will be maintained at substantially the same level in each container and its supply reservoir, but when the apparatus is in operation the water will rise in the supply reservoirs above the level of the water in the containers. The delivery reservoir Il may be suppliedwith water in any suitable manner and, as here shown, a supply pipe 20 extends through the bottom wall 8 into the reservoir Il and may be connected, either directly or indirectly, with a pump or other source of water supply. The delivery reservoir communicates with the two supply reservoirs at points above the normal level o f the water in the supply reservoir, and, in the present instance, it is provided with 4outlet openings 2| arranged above the level 'of the outlet openings Il of the corresponding containers. Preferably the outlet openings 2i are on the same level. Thus the water which is delivered from the reservoir l1 to thesupply reservoirsI I8 will fall from the openings 2| to the level ofd'the water in the supply reservoirs and will thus be aerated and all air and gas contained therein released. Also any oil in the water will rise to the surface -in thel supply reservoirsand will not be delivered to the containers. Further, this method of supplying water to the containers avoids the delivering of the water at such pressure. as to disturb the mineral beds and possibly float part of the mineral out through the discharge openings. When no water is being softened the water in each container and its supply reservoir will be at substantially the same level and when water is.de

livered to` the supply reservoir the level in the' reservoir will rise and the pressure in the container will be gradually increased and the level of the water therein raised so that it will flow over the edges of the collecting trough Ha, but this is accomplished. slowly and without any sudden inrush of water or any high pressure which would disturb the mineral bed. Further, this method of delivering water to rthe containers causes the same quantity of water to be softened in each container even though the resistance to the flow through one container may be greater than the resistance to the flow through the other container, because of a tighter packing of thev mineral or for other reasons. If the resistance to the flow through one container is greater than through the other container the water in the supply reservoir for that container will rise to a higher level than it rises in the other supply reservoir and the increased lhead will exert a. greater pressure within. the container and will force the water through the mineral, at the saine rate of ow as in the other container, and when the delivery of water to the two supply reservoirs has been interrupted the water will stand above the normal level in the one reservoir andl will continue to flow to the corresponding container until it reaches normal level. 'I'hus at the end of the softening operation the same amount of water has been softened by both containers and consequently the timing of the reconditioning mechanism will be the 'same for both containers. It will beY obvious that the supply reservoir may be arranged at any suitable height with relation to the container but it is desirable that the'bot` level of the outlets for .the containers, as this would result in trapping air in the conduits which, when discharged into the container, would agitate the mineral and cause portions of it to flow out with the water. If the bottoms of the reservoirs are at the level of the outlets the water will be entirely discharged from the reservoirs when the apparatus is not in operation brit will stand in the conduits at the level of the water in the containers. The delivery reservoir i1 is desirable in a multiple container unit but it is not necessary when a single container is used, as the water may then be delivered to the supply reservoir in any` is delivered to the containers through the respective' supply reservoirs and the conduits which connect the same with the containers. For this purpose brine pipes 22 extend intothe respective supply reservoirs and have their discharge ends arranged close to and in line with the outlet openings Ica so that the brine will be discharged directly into those openings and will be carried through the supply pipes I8 to the container. The

pipe with relation` to the outlet is such that the arrangement of the discharge end of the brine brine will not mix with the water in the supply reservoir but willbe carried by that water into the pipe I8 and theremixed with the water to provide a salt solution of the proper strength. Be-

.cause of this arrangement no brine will remain in the supply reservoirs at the end of the reconditioning operation. The brine may be supplied to the brine pipes 22 from lany suitable source and any suitable means may be employed for controlling the supply and for timing the delivery of the brine to the containers. As shown in Figs. 2, 3 and 4, the brine distributing apparatus is supported at a level higher than the supply 'reservoir IB and is, inl thefpresent instance,

mounted on the top wall of the structure in which this reservoir is formed. This distributing apparatus comprisesa receptacle 23, see Figs. 4 and 8, which is divided by partitions 24 into a plurality of compartments. When used in connection witha double softening unit this l'receptacle is/ preferably provided with four compartments two of which, as shown at 25, are relatively small and constitute supply receptacles for the brine. Pipes 26 lead from the lower portions of these brine supply receptacles and are connected with the upper ends of the brine pipes 22 which extend above the reservoirsu in which they are mounted, so that the brine will ow by gravity from the.

which in turn is connected through suitable ,re"

ducing gearing, arranged within a casing 33, with an electric motor 34. 'I'he speed-of the motor is very greatly reduced by the gearing so that the basin 23 rotates slowly and thenozzle moves into and out of 'line with the brine 'receptacles 25. When the nozzle is in line with one of the brine receptacles it will deliver brine to that receptacle and the brine will flow through the pipes 25, 22 and I8 to the corresponding container, and the supply of brine to. the container will be continued so long as the nozzle is in line'with the receptacle 25 but it will be discontinued as soon as the nozzle passes beyond that receptacle. The larger receptacles within the structure 23, which are arranged between the receptacles 25, as shown at 35, are connected by pipes 35 with the brine tank 5 so that any brine which is discharged from the nozzle 29 into the larger receptacles 35 will be returned to the brine tank. It is preferable, however, as will hereinafter appear, to interrupt the delivery cf brine by the nozzle when the latter is out of line with both brine .receptacles 25. The upper edges of the partitions 24 are prefer.- ably depressed slightly below the upper edge of the wall of the structure 23 to prevent splashing (see Fig. 11.) The partitions 24 extend substantially radially to the axis about which the nozzle rotates and have thin upper edges, the edges being preferably beveled. inwardly. The discharge opening of the nozzle 29 is elongated radially to the axis about which the nozzle rotates and is relatively narrow so that it will pass quickly across the partitions 24. "I'he arrangement of the partitions and of the nozzle not only causes communication between the nozzle and the receptacles to be quickly established and interrupted but also reduces splashing to a minimum. The

- pipe 31, which is connected with a pump 33 driven e ".water to removethese substances and for this brine may be supplied to the nozzle in anysultable manner. When, as in the present instance, the nozzle is carried by a basin I prefer todeliver the brine Ito the basin through a brine supply by an electric motor 39 and having a suction pipe 4II leading from the brine tank 5. I also prefer to provide this brine supply pipe with a needle valve 4I by means of which the flow of brine therethrough may be regulated, thus enabling the soft water in the reservoir 5 to be maintained at a lselected average hardness,with all the water which is delivered to the soft water receptacle passing through the softener.

In order to prevent the brine which is discharged from the container from. entering the.

soft water reservoir I have mounted in the space between the two'containers a' drain trough 42 whichis movable into line successively with the discharge openings I3 of the outlet troughs TI2 and has van outlet 43 arranged to discharge intoA adrain basin 44 which is connected with a drain pipe 45. Preferably this drain trough 42 is secured to the lower end of the shaft 33 which carriesthe rotating nozzle of the brine distributing y apparatus so that this nozzle and the drain trough are maintained in xed relation one to the other. relation is such that the drain trough will be moved into line with the discharge opening for one of the containers at approximately the same time that the nozzle moves into beyond-the brine receptacle. Thus the fresh wa ter which flows through the container after the spply of brine has been cut cir will wash out of the container the brine that remains therein and this wash water is also delivered to the drain trough. After an interval sufficient to thoroughly wash the mineral in the container free from salt the drain trough moves beyond the discharge opening and the water from the container is againl delivered to the soft water reservoir. In order to prevent the splashing of the brine or wash water eut ofthe drain trough, and thus permitting it to enter` the soft water reservoir, the discharge openings I3 of the outlet troughs for the containers are in the form of narrow slots, as shown in Fig, 1, arranged substantially radially tothe axis of the rotating trough and the side walls of that trough are so arranged that each will -be substan` tially parallel with the discharge slot as it passes the same. This permits of a very quick passage 'of thetrough into and out of line with the discharge opening. The upper edges of the trough are made thin and are preferably beveled inwardly, 8S shown in Fig. '1, so as to direct the fluid striking the same into the trough.

The water to be treated is delivered tothe apparatus by a pump or pumps 45 operated by motors 41 and the soft water is delivered from the reservoir 5 to the service line 4 5 by a pump 43 drivenby an electric motor 50. The connection betweenD the p`ipe 23 and the hard water pumps 46 may be direct or it may be through suitable a intermediate controlling or-treating apparatus. Some waters contain foreign substances such as corrosive gases, iron, sulphur and the like, which it is desirable to remove before introducing the water into the mineral containers. If iron is in solution itmay be removed by the ,mineral but .when the iron is in suspension or the water contains large quantities of free carbon dioxid, or other substances. it is often desirable to treat the purpose I have provided the present installation with an aerating and filtering apparatus, yIn the arrangement shown, the main structureA of the plant is provided in its upper portion, preferably on the roof, with a basin 5I in or above which are supported on framework 52 a plurality of trays 53 to which the water is delivered through a pipe 54. If desired, a flow regulator 55 may be interposedin the pipe 54 to maintain a uniform new or water. to the trays. As the water flows from one tray to the other itis oxidized and gases are freed therefrom. -If desired, the trays may contain suitable substances for furthertreating the water. The water then flows from the basin 5I by gravity through pipes 53 and 51 to a pressure l- Iter 53 with which the pipe 25 is in the present instance connected.` In order that the lter may be back washed for the purpose of cleaning the same the pipe 231s provided with a valve 5.3 and the outlet for the filter is connected by a branch" pipe n with-the pipe-'ss anda vaive sl is inserted in `the pipe 60. A valve 62 is interposed in the pipe i8 in advance of the pipe 51 and the latter ist connected with a drain pipe 63 in which there is a e valve 84. Normally the valves 62 and 58 are open and the valves 8| and 84 are closed. When it is desired tobback wash the filter the valves 58 and 62 are closed and thevalv'es 8| and 64 opened so that water flows from-the basin 5l through the l0 filter in a reverse direction to the drain.

l Water may be supplied to the salt reservoir 8 from any suitable source and under any suitable control. 'I prefer to take the filtered water from the pipe 2li and deliver the same to the salt reser- 16. voira suitable float valve or other device being provided to control the level of the water in the reservoir. 'When a valveand float are mounted within the salt reservoir the action of the salt often interferes with the action of the valve and 20. salt crystals accumulating on the float interfere.)

with its proper operation. I have therefore provided an intermediate water supply tank 65 which is connected withy the pipe by a small pipe'BS and is connected with the salt tank by a pipe 61.

A valve 68 is mounted within the tank 65 to con- ,45 12 and tbe-brine pump circuit 13.

trol the ilow of water through the pipefSB and is operated by a oat. The valve and iioat. are so arranged that the level of the water in tank 65 will be maintained at substantially the desired normal level of the brine in the salt Ireservoir 6.

y'.l'hus the valve and the float are subjectedonly to the action of fresh water.

j The supply of water to the apparatus and the operation of the reconditioning mechanism is i automatically controlled in accordance with the amount of soft water used. I have, in the present instance. provided a master switch to control the operation of the supply pump, the brinepump and the reconditioning mechanism and this mas- 40' terA switch is controlled primarily by a float in 4the soft water reservoir. .In Fig. 9 of the drawings I have shown the master switch at 68, which -is interposed in the main circuitv10 and controls the supply pump circuit 1|, the mechanism circuit The switch is movedto its cled position by a solenoid 14 and when the solenoid is deenergized the switch is opened by a spring 15. The solenoid circuit 16 is connected with a suitable source of current,l 5o such as the maincircuit, and is provided with a switch11 which is actuated by a float 18 in the soft water reservoir. The"arrangement is such that when the\water falls to a predetermined level the switch 11 will be closed and the solenoid 14 energized toactuate the switch and close the circuit through the several motors. When the `water-has been raised to the desired level the switch 11 will be opened to break the circuit i vtluough'the' solenoid 14 and thus permit the ilA switchto open. This float controlled switch is "zo switch 11.

i the event the float switch is openedduring thel l ,shown diagrammatically and it will be understood that in .practice a switch of the snap Aaction type or other suitable kind will be employed which will permit of a relatively great movement of the y 65 float before the switch is actuated. It is not de-v throughout the 'reconditioning period and willv prevent the solenoid from being deenergizedin aooavca reconditioning period; une man my be or my suitable character and is'illustrated as a disk" so connected with the mechanism which drives the shaft 8l that it will rotate at the same speed at which thatshaft rotates. The ispro'- 'fs vided with contact surfaces 8| so arranged that one of those surfaces will engage a stationary contact 82 approximately at the same timethat the'hrine nozzle ltmovesinto communication with one ofthe brine receptacles 2l, and will rell main in engagement with the nxed contactll luntil the drain trough 42 moves out of line with the discharge opening I8 of the containenj 'It is also desirable that' the brine' pump should operate only at such times as the nozzle 2l is in line is' with one'of the Vbrine receptacles 2i. Otherwise brine would be pumped continuously into the main receptacle 23 and during the water softoning periodwould merely flow back t0 the brine tank. I have therefore interposed inthecimuit alo'- 13`of the brine pump motor a switch which is automatically actuated to close that .circuit-at or just before the time that the brine nozzle passes into communication with one of the brine re,-

ceptacles and to break 'that circuit 'just as the 2'5'1 nozzle passes out of communication with the brine receptacle. This switclfisalso shown diagram-A matically as comprising a disk 83 connected with a part o f the mechanism which drives the shaft su so that a wurrome at the same speed as um ajo shaft. It is provided with two contact surfaces 84 so arranged-that one or the other of themwill =be moved into engagement with the stanonary contact 85 just 'as the brine nozzle 2l moves'linto line with one of the brine receptacles 2l and will 351' move out of engagement with the stationary contact at approximately the same tin/rei that the brine nozzles moves out of line with the brine receptacle. I have here shown the reconditioning mechanism as 'operated by an electric motor 40' but it will be obvious that a water motor could be used for this purpose andidriven by the water. from the main supply pump. Consequen the control of the pump would also, control the echanism motor andno additional controlling device 45- would be necessary.

The brine distributing mechanism abovedei scribed has the very important advantage fof being free from valves which might be corroded or otherwise1 interfered with by the brine .-soi 5g that they would notpr'operly close. It may in some installations, however, he preferable 'to use a simpler construction in' which the flow ot brine would be controlled by automatically operated valves. In Fig. 8 I have shown such a construction.` As there' illustrated; the brine Supply pipe 31 dischargesr into a brine receptacle 86 with which there-is associated a float actuated switch 81 to interrupt the circuit for the brine pump motor when the brine in the receptacle l. 60

reaches Aa predetermined level. The distributing pipe 88 leads from thelower portion of the' receptacle 86 to the brine pipes 22a which extend into the respective water supply'reservoirs I6. In the arrangement here shown branch. 55-

pipes 89 from the distributing pipe 88 are arranged to discharge into cups or flared upper ends 90 of the pipes 22a, the ends of the pipes 88 being spaced above the cups so that the flow of brine will bel visible.'r Mounted in each pipe 8870 is an electrically operated valve il, the lmagnets of which are3 controlledpby a switch connected with the' mechanism which -actuates'the shaft 30 and drain trough 42, which wiil''still:libe.re-5l ltained with this type of brixiedistributor. 757

f accenna as that shown in Fig. 9 for the control of the brine pump. .Such a switch will cause the brinei .valves 9| to be opened and closed at predetermined intervals controlled by the amount of water used. While these valves are subject to leakage because of corrosion or the accumulation of salt crystals thereon thisis not important in very large installations where any attendant is constantly present, because the attendant will quickly discover any leakage and properly adjust the valves. .l

In Fig. 10 I have illustrated another installation in which the mineral container is shown at 95 and hardl water is supplied thereto through a supply pipe 96. In the present instance, the hard water supply is electrically controlled, the water being delivered` to the pipe 96 by a pump 91 driven by an electric motor 98. An injector 99 is interposed in the supply pipe-96 and brine is) delivered to the injector through a pipe from a brine reservoir |0|. The delivery of brine is controlled by an electrically operated valve |02 interposed in the pipe |00. A discharge pipe |03 leads from the container 95 and has two branches |04 and |05.v The branch |04 leads to the point of discharge for the soft water and, in thepresent instance, discharges into a storage reservoir or tank |06, which maybe of any suitable size and may be arranged in any suitablev ylocation with relation to the' softening unit. The second branch |05 of the discharge pipe il the drain pipe and is controlled by an electrically operated valve |01.. The electrically operated valves |02 and |01 are controlled, respectively, 4by switches l|08 and'l |09 and the opera-` tion of these switches is controlled by an'electric motor ||0. In the present instance, the motor I0 is connected by gears |||A with a shaftA ||2 which carries cams ||3 and ||4 arranged to actuate, respectively, .the switches4 |00 and |09. These cams are so arranged that the two switches will be closed at approximately the same time to open the brine valve |02 and the drain valve |01. After an interval sumcient for the regeneration of the mineral the switch |09 is opened and-thevalve |02 closed and aftera further interval sufncient to wash out the con-i tainer the switch |09 is opened and the'valve |01 closed, thus restoring the softening operation. The electrically operated means for vactuating the valve switches is so controlled with relation t the means yfor supplying hard water to thecontainer that thegshaft ||2 will rotate .continuously while hard, water is being suppliedn to the container and consequently the switches will be controlled in accordance. with the quantity of water delivered tofthe'container:

In the vpresent instancethe pump motor 99 and the switch' controlling motor 0 are connected inl the `same circuit ||5 and this circuit is conrtrolled by a master switch. Preferably the master switch is automatically operated and-it is shown at ||9 as connected with a iioat' ||1 in ,the storage reservoir' |06, the arrangement being such thatwhen the water inthe stoi'age-res ervoir falls to a predetermined level the switchf will 'be 'clsed and vthe pump and reconditioning mechanism will be Jstarted in operation. When the water in the reservoirv rises to a predetermined heightthe switch will be opened and the l reconditioning mechanism stopped.

Pump 3nd have shown and described` certain em- WhileI A bodim'ents of my invention I wish it-to be understood that I do not desire to be limited to the deconduits leading from ply reservoirs to the lower ends of the respective ,ing its .discharge end tailstliereof Vas various modifications may occur a person skilled in the art.

Having now fully described my invention, what I claim as new and desire to secure by Letters I Patent, is:

l. In an apparatus of the character described, a container for water softening material having an outlet above the level of said material, a receptacle arranged alongside of said container, a partition dividing said receptacle into a delivery reservoir and a supply reservoir and having an opening to connect said reservoirsone with the other above the level of theoutlet for said con-l tainer, means for supplying water to said de-4 livery reservoir, and means for so connecting said supply reservoir with said container that the water will be maintained normally at substantially the same level in said supply reservoir and said container.

2. In an apparatus of the character described, a plurality of containers for water softening material each having an outlet above the level of a plurality o! containers for water softening material each having -an outlet above the level of the material therein, a supply reservoir for each con- `tainer, means for so connecting each container with its supply reservoir that the water-will be maintained normally at substantiallyvthe same level in said container and said supplyreservoir, a single delivery reservoir having communication with each supply reservoir at a point above the normal level ci.' the waterin that supply reservoir,l

and means for supplying water to said delivery' reservoir. u.

4. In a watersoftening unit comprising twocontainers for water softening material spaced laterally one from the other and each having an outlet above the level of the material therein, supply reservo'irs arranged between said containers,-

the lower ends of said supcontainers, a delivery` reservoir arranged between said supply reservoirs and having open communi-vv cation with each supply reservoir above the outletI for thecontainer with which that supply rester-55A voir is connected, and means for supplying water to said delivery reservoir.

5. In an apparatus of the character described. a container for water softening material having-` an outletabove the level of v said-material,` a hardv water supply reservoir, means formconnecting the lower portion of said supply reservoir with the lower portion of said container, means for delivering water to said supply reservoir, means i'ordelivering brine into the vlower portion of said supply reservoir adjacent said connecting means.

6. IIn an apparatus of the character described, ar conta`iner for water softening material having an outlet above the level ofI said material, a hardwater'supply reservoir having an outlet at4 the lower end thereoL'a conduit leading from said outletA to the brine pipe extendingl into said .reservoir` hav -v)' .-toi'the voutlet fcr Y lower portion ofisaid container, ,A means for4 supplying water to 'said reservoir, a

said reservoir; means to control the flow of brine through said brine pipe.

'1. Inl a water softening apparatus comprising a 'container for water softening material, and means for supplying water to be softened to said container, a brine receptacle, means for connecting said brine receptacle with said container, a brine delivery device mounted for movement into and out of a position to deliver brine to said brine receptacle, means to actuate said device, and means controlled according to the positionA of said device to supply brine thereto when said device is in a position to deliver brine to said receptacle and to interrupt said supply when said device is moved out of its delivery position. Y 8. In a water sof apparatus comprising a container for water softening material and means for supplying water to be softened to said container, a brine receptacle having its upper .end open, means for connecting said brine receptacle with said container, a brine delivery nozzle rotatably mounted for movement into and out of line with the open end-of said'brine receptacle,

' and means tamme said nome.

9. In a water softening apparatus, comprising a container lfor water softening material and means for supplying water to be softened to said container, a brine receptacle having its upper end open, means for connecting said brine receptacle with said container, a brine delivery nasale rotatably mounted for movement into and out of line with the open end of said brine receptacle, means'to rotate said nozzle, and means controlled according to the position of said nome to supply brine thereto when it is in line with;

the open end of said brine receptacle and to interrupt said supplywhen said nozzle is out of line with said open end of said receptacle..

- l0, In a water softening apparatus comprising a container for water softening material, and

' means for supplying water to be softened to said container, a structure having two receptacles,^one of which isrelatively small, the other relatively a brine deuvem nome rotatably mounted above said structurefor movement into line with said receptacles vely, means for connecting the smaller receptaclewith said container, a return conduit leading from the larger receptacle, and means for rotating said nozzle.

- 1 1. In a water softening apparatus comprising a container for water softening material, and

means-for supplying water to be softened to said container, a brine receptacle, means for connectlnk said brine receptacle with said container, a

delivery device rotatably supported above said receptacle and comprising a nomle having a relatively narrow` radial discharge opening, the

side walls of said receptacle being arranged substantially radiallyto the axis of said delivery de-V vice, and meansfor actuating said delivery device to cause said nossle tomove into and outV of a position to discharge'into said receptacle.

' having means for connecting the same'with.

12.V In a water soffeninir DDlrtus comprising a container for watersoftening material having an outlet, and meansforsupplying water to.

be softened to said container, a brine receptacle said container, a brine delivery device mounted for rotation into and out of a position to deliver lbrixieto said brine receptacle, a drain trough mounted for rotation into and out of a positionl to receive. fluid from the outlet for said container, said outlet comprising a relatively narrow slot and the' side walls of said drain'trough being arrangedtok extend substantially parallel with time that said said slot when passing the same. and to.

rotate said brine delivery device and said drain trough in unison.

13. In a water softening apparatus comprising a container for water softening material having an outlet, means for supplying water to be softened to said container, and means for delivering brine to said container, adrain trough mounted for rotation into and out of a position to receive iluid from the outletfor said container, said outlet comprising a relatively na-r- ,row slot and the side walls of said drain trough being arranged to extend substantially. parallelA with said slot when passing the same and having their upper edges sloping inwardly, and means to rotate said drain trough.

14. In a water softening apparatus comprising a container for water softening material. having an outlet, and means for supplying water to be softened to said container, a brine reservoir,

means for delivering brine from said reservoir to .said container, a tank connected with a source of supply for fresh water and with said brine reser voir, a valve to control the flow of water thereto,

and a float in said tank to actuate said valve.'

said valve and said ,iloat being arranged to maintain the level of the water in said tank at approximately the normal level of the brine in sai reservoir.

15. In a water .softening apparatus,- a'container for water softening material having an outlet, means to supply hard water to said contain-l said valve and said float being arranged to main-v tain the'water in said tank at approximately the' normal level of thebrine in said reservoir.

16. In a water softening apparatus, a container forwater softening material, means to supply hard water to said container, electrical means for operating said hard water supply means, valveless reconditioning a motor to oper--- ate said reconditioning mechanism, and a master switch to control the operation of said electrical means and said motor.

17. In a water softening apparatus. a container for water softening material, means'to supply hard water to said container, electrical means for operating sai'd hard water supply means, valveless reconditioning mechanism, a motor to operate said reconditioning mechanism. and means to supply brine .to said reconditioning mechanism, and a'msster switch to control the operation of said electrical means, said brine supply means and said motor.

' 18. In s.l water softening apparatus, a container for water softening material, means to supply hard water to said container, 'electrical means l for operating said hard water supply means.'

nism, a master switch to control the operation of 'said hard wafer supply means, said brine s'upply means and said motor, and means for interrupting the brine supply during a portionof the' reconditioning means yis in op.

eration. Y

19. In a water softening apparatus. a container for water softening Jmaterial, means to supply hard water to said container, electrical means for aooanea operating said hard water supply means, a brine reservoir, a brine receptacle, means to deliver brine from said reservoir to sai receptacle, electrical means for operating id brine delivery means, means to supply brine from said receptacle to said container, electrical means for operating. said brine supply means, and a master switch to control the, several electrically operated means'. i

20. In a water softening apparatus, a container for water softening material, meansfor supplying hard water to said container, electrical means for operating said hard water supply means, a brine pipe to supply brine to said container, a drain pipe leading from sad container, valves interposed respectively in said brine pipe and said drain pipe, electrical means for operating said valves, switches to control the respective electrical means, means to actuate said switches, electrical meansfor operating said actuating means and a float-operated master switch to control the electrical means for operating the hard water supply m ns and the switch actuating means.

1. In a water softening apparatus', a container for water softening material, means for supplying hard water to saidccontainer, electrical means for operating said hard water supply means, a brine pipe to supply brine to said contajner, a drain pipe leading from said containeyalves interposed respectively in said brine pipe and said drain pipe, electrical means for operatng said valves, switches to control the respective valves, electrically controlled means to actuate said switches, a reservoir to receive softened water from salu container, a switch connected in circuit with said hard water supply controlling means and said switchl actuating means, and means controlled by the level of the water in said reservoir to actuate the last mentioned switch.

22. In a water softening apparatus, a container for water softening material having van outlet, a reservoir to receive softened' water from said outlet, a pump to supply water to 'ne softened to said container, an electric motor for operating said pump, reconditioning mechanism, an electric motor to operate said reconditioning mechanism,

Aa'. 4pump to supply brine to said reconditioning mechanism, `an electric motor to operate said brine pump, .a switch to control the operation of said motors, and a oat in said reservoir to control the switch. y

23. In a water softening apparatus, a container for water softening material having an outlet, a' reservoir to receive softened water from'said outlet, a pump to supply water to be softened to said container, an electric motor for operating said pump, reconditioning mechanism, an electric motor to operate said -reconditioning mechanism. a pump to supply brine to said reconditioning 50 mechanism. an electric motor to operate said brine pump, a master switch to control said motors. a magnet to actuate sad switch, a switch to control `said magnet, and a float in said reservoir to control the last mentioned switch.

24. In a water softening apparatus, a container A for,water softening material having an outletl a reservoir to receive softened .water from s'ad outlet, a pump to supply water to be softened to said container, an electric motor for operating saidpump, recondtioning mechanism, an electric motor to operate said reconditioning mechanisxma l pump to supply brineto said reconditioning mechanism, 'an electric motorto `operate Isaid brine pump, amaster switchy to control said motors, amagnet to actuate saidswitch. a circuit for trical control meansfor botli said means. an elecsaid magnet, a switch in said magnet circuit.' a'- float in said reservoir to control said magnet switch, and a switch connected across the terminals of said magnet switch and so'connected with said reconditioning mechanism that it will close .5 Y

the magnet circuit independently of said magnet switch so long as the reconditioning mechanism is in operation.

25. In a water softening apparatus, a container for water softening material having an outlet. mi

a reservoir to receive softened water from said outlet, a pump to supply water to be softened to said container, an electric motor for operating said pump, reconditioningy mechanism, an,electric motor to operate said reconditioning mechal5:

nism, a pump to supply brine to said reconditioning mechanism, an electric motor to operate said brine pump, a master switch to control said mo tors, a magnet to actuate said switch, a switch to control said magnet, a float in said reservoir 2Q.;

to control the last mentioned switch, and a switch in circuit with the motor for, said brine pump and so connected with said reconditioning mechanism that it will be closed during a portion only of the time said mechanism ls in operation.

v 26. In a water softening apparatus, a container for water softening material having an outlet, a reservoir to receive softened water from said outlet, apparatus for supplying hard water, electrical means for operating said apparatus, appa- 30 ratus forsupplying regenerating solution to said container, electrical means for operating said apparatus, a switch to control the electrical means, a magnet to actuate said switch, .a switch to control said magnet and-a float in said reser- 35 voir to control the last mentioned switch.l

27. In a watersoftening apparatus, a container for water softening material having an outlet, ar reservoir to receive softened water from said outlet, means for supplying water to be softened '40 to said container, electrical means for operating said means, means for reconditioning the water softening material, electrical means lfor operating said reconditioning means, a mastenswitch to control both electrical means, a magnet to actuate said switch,.a switch to control said magnet,

a float'in said reservoir to control the last mn- 1 tioned switch, and means controlled by said reconditioning means to prevent said magnet frombeing deenergized while said reconditioning mechanism is in operation.

428. In a water softening apparatus, a container for water softening material having an outlet, a reservoir to receive softened watevfrom said outlet, a pump to supply raw water to said container, an electric motor'for operating said pump,l reconditioning means, an electric motor vto control said reconditioning means, an electric circuit connecting said motors to a source of electric energy, a switch in said circuit to control lthe operation of said,

reservoir to control the switch.

29. A water softening apparatus adapted to perform the operations of softening and regenerating with a continuous supply of hard water and tov furnish softened water continuously 'and 65 ing mechanism comprising 'means adapted y'to dl.- '1.0

vert water from each outleti to waste, electricalmeans for operating said diverting means, means adapted` to feed brine into the inlet, electrical' means for operating said brine feed means, elecmotors, and a float in 60 tric circuit connecting said electrical control means to a source of electrical energy, oat switch Y control means being adapted to allow softening to take place for a deilnite interval, then to actuate the diverting means and the brine feed means substantially simultaneously whereby brine is carried into and through a container by the hard water, and spent brine issuing from an outlet is diverted to waste, said control means being further adapted to disconnect the brine feed means after 'a deilnite time and to leave the diverting means in action for a further predetermined time for washing, and then to disconnect the diverting means so as to allow hard water 'to pass through the softener int'o the reservoir, said control means allowing cycles of brining. washing and softening to take place continuously until the water in the reservoir has been raised to the predetermined level.

30. InI an electrically controlled water softening apparatus a container for water softening material having an outlet. a reservoir to receive softened water from the outlet, a pump to supply raw water to said container, electrically controlled powermeans for operating the pump, reconditioning means for the softener, electrically operable means for controlling the reconditioning means, electrical circuits for said means and for the said electrically controlled power means,

means responsive to the level of water in the reservoir and electrical switch means adapted to be actuated by the level-responsive means and to control the circuits for the pump power means and the control means for the reconditioning means.

l EDWARD T. TURNER. 

